A machine and a method to carry out workings on a sheet of a sufficiently rigid material is suitable to make containers. The machine includes a transverse working head guided by a first transverse guide member, one or more longitudinal working heads, each selectively positionable in a desired transverse position, guided by at least a second transverse guide member parallel to the first transverse guide member; and positioning mechanism configured to cooperate with each longitudinal working head in order to selectively position it in the desired transverse position.

A printing platform includes a printing engine with one or more printheads arranged such that the ink drops are jetted vertically upwards against the action of gravity; and a substrate transportation system where the normal to the surface in contact with the substrate is parallel and with opposite direction to the travelling direction of the jetted ink drops. It is necessary to counteract the weight of the substrate during the printing process to avoid it from falling under the action of gravity. This is achieved through any of a mechanical element that interferes with the falling of the substrate and that keeps it in place; or a system that generates adhesion forces between the element that transmits the motion to the substrate, typically a conveyor belt, and the substrate through the action of electrostatic forces, an air pressure differential between both faces of the substrate, or any other suitable mechanism.

An agitator for agitating sheets of material passing through a sheet transport device that has upper and lower guide sections defining a sheet transport path therebetween. The agitator includes first and second sets of rollers each having a roller axis of rotation and a width, and the rollers are mounted to at least one holder such that the axes of rotation of the rollers are radially spaced from a line and such that rotating the at least one holder around the line causes the rollers to orbit around the line. At least one support supports the holder for rotation around the line, and the set of first rollers is spaced from the set of second rollers in the direction of the line by a distance greater than the width of the rollers. Also a sheet transport device including the agitator.

A cutting unit for cutting preparation features in a web of sheetlike material is provided. The cutting unit has a first part with a rigid base portion, at least one first cutting tool configured to cut a first preparation feature in the web of sheetlike material, and at least one second cutting tool configured to cut a second preparation feature in the web of sheetlike material. The at least one first and second cutting tools are attached to the base portion and located at a distance from each other, wherein at least one of the at least one first or second cutting tools is supported by a flexible support that is located in the rigid base portion of the first part.

The invention relates to a line for manufacturing packagings (2) producing folding boxes (CA1, CA2) from plate elements (4), which comprises a feeding station (20), a shaping unit (33) which consecutively shapes the plate elements (4) by slitting, scoring and cutting operations, provided with pairs of shafts (230.sub.a-233.sub.a, 230.sub.b-233.sub.b) and a cutting unit (24), which engage to produce, in the shaped plate element (3), two juxtaposed folding box layers (P1, P2), arranged transversely to the direction of transport (FD), which are associated in series, and connected to one another by attachment points (45), a folding/gluing unit (26) which forms folded assemblies (5) by folding and gluing the shaped plate elements (4), a counting/ejection unit (27) which forms stacks of folded assemblies (6, 7), and a unit (29) for separating folding boxes comprising means arranged to produce, by breaking the attachment points (45), two separate batches (8.sub.1, 8.sub.2) of stacked folding boxes from each stack of folded assemblies (6, 7).

A system that converts sheet material into packaging templates includes a converting assembly that performs conversion functions, such as cutting, creasing, and scoring, on the sheet material as the sheet material moves through the converting machine in a first direction. The converting assembly may be mounted on a frame such that the converting assembly is elevated above a support surface. One or more longhead converting tools performs conversion functions on the sheet material in a first direction and a crosshead converting tool performs conversion functions on the sheet material in a second direction in order to create packaging templates.

In one aspect, there is provided a combination for use in readying a cutting cylinder is rotatably mounted to a frame in a box-forming production line. The cutting cylinder has a cylinder reference indicium. The combination includes a transfer member with a transfer member reference indicium thereon, a cutting member that includes a base and a cutting blade, and a connector structure that is configured to releasably mount the cutting member to the transfer member. The cutting member is movable to a selected distance along the first axis from the transfer member reference indicium. The connector structure includes a locking structure positionable in an unlocking position for separating the cutting member and the transfer member, and a locking position to lock the connector structure to the transfer member, so as to hold the cutting member at the selected distance from the transfer member reference indicium.

In one aspect, there is provided a combination for use in readying a cutting cylinder is rotatably mounted to a frame in a box-forming production line. The cutting cylinder has a cylinder reference indicium. The combination includes a transfer member with a transfer member reference indicium thereon, a cutting member that includes a base and a cutting blade, and a connector structure that is configured to releasably mount the cutting member to the transfer member. The cutting member is movable to a selected distance along the first axis from the transfer member reference indicium. The connector structure includes a locking structure positionable in an unlocking position for separating the cutting member and the transfer member, and a locking position to lock the connector structure to the transfer member, so as to hold the cutting member at the selected distance from the transfer member reference indicium.

The operation result evaluation system comprises: an operation result information generation part configured to generate operation result information including a production count and an achieved operating time period; and an operation result evaluation device for, after completion of production of corrugated paperboard boxes for a given order, evaluating an operation result of the box making machine. The operation result evaluation device is operable to: with respect to each order, calculate an additional operating time period which is a difference between a target operating time period and the achieved operating time period; generate analytical information regarding an operating time period (FIG. 8) in each order; with respect to each of the entirety or part of a given number of orders, generate comparative information (FIG. 9); and cause the generated comparative information to be transmitted to a user terminal.

A machine for making corrugated paperboard boxes form corrugated paperboard sheets includes a slotter device with a blade that forms slots in the corrugated paperboard sheet. The machine can handle various sizes and configurations of corrugated paperboard sheets and can determine if the blade of the slotter device has a suitable length to form slots in each of the various corrugated paperboard sheets, using parameters including a circumferential length (N) of the slotter cylinder and dimensions (E, F, G) of the corrugated paperboard sheet.